Title :
Modeling of hole inversion layer mobility in unstrained and uniaxially strained Si on arbitrarily oriented substrates
Author :
Pham, A.T. ; Jungemann, C. ; Meinerzhagen, B.
Author_Institution :
TU Braunschweig, Braunschweig
Abstract :
The hole inversion layer mobility of in-plane uniaxially strained Si is modeled by a microscopic approach. For an arbitrary crystallographic surface orientation the two dimensional hole gas subband structure is calculated by solving the 6 times 6 koarr ldr poarr Schrodinger equation self-consistently with the electrostatic potential. Three important scattering mechanisms are included: optical phonon scattering, acoustic phonon scattering and surface roughness scattering. The model parameters are calibrated by matching the measured low-field mobility of relaxed Si on (001) Si wafers. The calibrated model reproduces available channel mobility measurements for unstrained and uniaxially strained Si on (001), (111) and (110) substrates.
Keywords :
Schrodinger equation; electron mobility; silicon; substrates; surface roughness; two-dimensional hole gas; 2D hole gas; Schrodinger equation; Si; acoustic phonon scattering; arbitrarily oriented substrates; channel mobility; electrostatic potential; hole inversion layer mobility; optical phonon scattering; surface orientation; surface roughness scattering; uniaxially strained silicon; unstrained silicon; Acoustic measurements; Acoustic scattering; Crystallography; Electrostatic measurements; Microscopy; Optical scattering; Phonons; Rough surfaces; Semiconductor device modeling; Surface roughness;
Conference_Titel :
Solid State Device Research Conference, 2007. ESSDERC 2007. 37th European
Conference_Location :
Munich
Print_ISBN :
978-1-4244-1123-8
Electronic_ISBN :
1930-8876
DOI :
10.1109/ESSDERC.2007.4430960
